Systems and methods for non-time smearing detection mechanisms for magnetic cards and devices

ABSTRACT

A detection activity of a card may be sensitive to capacitance changes in one or more pads on the card, where a capacitance change detected in a pad during a first time period does not affect a capacitance change detected in the pad during subsequent time period(s). Accordingly, the detection activity may remain sensitive to a faster-moving device with greater accuracy in a determination of position, velocity and/or acceleration of the faster-moving device in relation to the card. A second detection activity may follow a first detection activity, which may increase a probability of a successful communication sequence subsequent to the first detection activity.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims the benefit of U.S. Provisional Patent Application No. 61/740,173, titled “SYSTEMS AND METHODS FOR NON-TIME SMEARING DETECTION MECHANISMS FOR MAGNETIC CARDS AND DEVICES,” filed Dec. 20, 2012 (Attorney Docket No. D/129 PROV), which is hereby incorporated by reference herein in its entirety.

BACKGROUND OF THE INVENTION

This invention relates to magnetic cards and devices and related systems.

SUMMARY OF THE INVENTION

A card may include a dynamic magnetic communications device, which may take the form of a magnetic encoder or an electromagnetic generator. A magnetic encoder, for example, may be utilized to modify information that is located on a magnetic medium, such that a magnetic stripe reader may then be utilized to read the modified magnetic information from the magnetic medium. An electromagnetic generator, for example, may be provided to generate electromagnetic fields that directly communicate data to a read-head of a magnetic stripe reader. An electromagnetic generator, for example, may communicate data serially to a read-head of the magnetic stripe reader. An electromagnetic generator, for example, may communicate data in parallel to a read-head of a magnetic stripe reader.

All, or substantially all, of the front surface, as well as the rear surface, of a card may be implemented as a display (e.g., bi-stable, non bi-stable, LCD, or electrochromic display). Electrodes of a display may be coupled to one or more touch sensors, such that a display may be sensitive to touch (e.g., using a finger or a pointing device) and may be further sensitive to a location of the touch. The display may be sensitive, for example, to objects that come within a proximity of the display without actually touching the display.

A dynamic magnetic stripe communications device may be implemented on a multiple layer board (e.g., a two-layer flexible printed circuit board). A coil for each track of information that is to be communicated by the dynamic magnetic stripe communications device may then be provided by including wire segments on each layer and interconnecting the wire segments through layer interconnections to create a coil. For example, a dynamic magnetic stripe communications device may include two coils such that two tracks of information may be communicated to two different read-heads included in a read-head housing of a magnetic stripe reader. A dynamic magnetic communications device may include, for example, three coils such that three tracks of information may be communicated to three different read-heads included in a read-head housing of a magnetic stripe reader.

Input and/or output devices may be included on a card, for example, to facilitate data exchange with the card. For example, an integrated circuit (IC) may be included on a card and exposed from the surface of the card. Such a chip (e.g., an EMV chip) may communicate information to a chip reader (e.g., an EMV chip reader). An RFID antenna or module may be included on a card, for example, to send and/or receive information between an RFID reader and the RFID included on the card.

One or more detectors may be provided, for example, to sense the presence of an external object, such as a person or device, which in turn, may trigger a communication sequence with the external object. Accordingly, for example, timing aspects of an information exchange between an external object and the various I/O devices implemented on a card may be determined by a processor of a card.

A sensed presence of an external object or device may include the type of object or device that is detected and, therefore, may then determine the type of communication that is to be used with the detected object or device. For example, a detected object may include a determination that the object is a read-head housing of a magnetic stripe reader. Such an identifying detection, for example, may activate a dynamic magnetic stripe communications device so that information may be communicated (e.g., electromagnetically communicated) to the read-head of the magnetic stripe reader.

One or more read-head detectors, for example, may be provided on a card. The one or more read-head detectors may be provided as, for example, conductive pads that may be arranged along a length of a card having a variety of shapes. A property (e.g., a capacitance magnitude) of one or more of the conductive pads may, for example, change in response to contact with and/or the proximity of an object.

A card may, for example, be swiped across a read-head of a magnetic stripe reader, such that a series of conductive pads arranged along a length of the card may be used to sequentially detect the presence of the read-head as the read-head moves in relation to the card. In doing so, for example, a series of detections (e.g., the capacitance magnitude of a series of conductive pads may increase and/or decrease) which may be indicative of a direction of a card swipe, a velocity of a card swipe and/or an acceleration of a card swipe.

In some instances, a width of a read-head may be wider than a single conductive pad (e.g., a read-head may span a width that may be substantially equal to a width of two conductive pads). As a result, more than one conductive pad may exhibit a change in capacitance magnitude when, for example, a read-head comes into contact with two or more conductive pads or when a read-head is positioned proximate to two or more conductive pads.

Nevertheless, rules may be implemented, for example, whereby a property change (e.g., an increased and/or decreased capacitance magnitude) detected in any one conductive pad during a first measurement period may not be allowed to affect a property change (e.g., an increased and/or decreased capacitance magnitude) detected in the same conductive pad during a second measurement period. Accordingly, for example, the accuracy of position, velocity and/or acceleration detections may not be affected by an analysis of property changes induced within one conductive pad over multiple periods of time. In so doing, a speed of a card swipe, for example, may be increased without sacrificing a detection accuracy of the card swipe (e.g., without losing the ability to detect a location, velocity and/or acceleration of a read head or contact with a read head in relation to a card being swiped through the read-head housing).

False alarm detection may be implemented to reduce occurrences of false alarms. For example, certain objects (e.g., a finger) may cause a processor of a card to detect, for example, a presence of a read-head housing of a magnetic stripe reader when, in fact, no read-head housing is present. In such instances, knowledge of, for example, a previously detected card swipe and associated direction may allow a second detection to be made, whereby a second read-head detection that is consistent with the originally detected card swipe direction may enable verification of a legitimate card swipe and, therefore, may enable a successful communication sequence with a magnetic stripe reader whose presence has been detected and verified.

For example, an analysis of a capacitance magnitude change of one or more conductive pads of a first row of conductive pads may be performed to determine, for example, a presence of a read-head and a direction of movement that the read-head exhibits relative to the first row of conductive pads. A subsequent analysis of a capacitance magnitude change of one or more conductive pads along a second row of conductive pads in the same direction as previously detected may serve to legitimize a first detection of a read-head and, therefore, may increase a probability that a successful communication sequence between the card and the magnetic stripe reader may transpire.

BRIEF DESCRIPTION OF THE DRAWINGS

The principles and advantages of the present invention can be more clearly understood from the following detailed description considered in conjunction with the following drawings, in which the same reference numerals denote the same structural elements throughout, and in which:

FIG. 1 is an illustration of a card constructed in accordance with the principles of the present invention;

FIG. 2 is an illustration of a card constructed in accordance with the principles of the present invention;

FIG. 3 is an illustration of circuitry, and associated waveforms, constructed in accordance with the principles of the present invention;

FIG. 4 is an illustration of a card constructed in accordance with the principles of the present invention;

FIG. 5 is an illustration of a card constructed in accordance with the principles of the present invention; and

FIG. 6 is an illustration of process flow charts constructed in accordance with the principles of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 1 shows card 100 that may include, for example, a dynamic number that may be entirely, or partially, displayed using a display (e.g., display 106). A dynamic number may include a permanent portion such as, for example, permanent portion 104 and a dynamic portion such as, for example, dynamic portion 106. Card 100 may include a dynamic number having permanent portion 104 and permanent portion 104 may be incorporated on card 100 so as to be visible to an observer of card 100. For example, labeling techniques, such as printing, embossing, laser etching, etc., may be utilized to visibly implement permanent portion 104.

Card 100 may include a second dynamic number that may be entirely, or partially, displayed via a second display (e.g., display 108). Display 108 may be utilized, for example, to display a dynamic code such as a dynamic security code. Card 100 may include third display 122 that may be used to display graphical information, such as logos and barcodes. Third display 122 may be utilized to display multiple rows and/or columns of textual and/or graphical information.

Persons skilled in the art will appreciate that any one or more of displays 106, 108, and/or 122 may be implemented as a bi-stable display. For example, information provided on displays 106, 108, and/or 122 may be stable in at least two different states (e.g., a powered-on state and a powered-off state). Any one or more of displays 106, 108, and/or 122 may be implemented as a non-bi-stable display. For example, the display is stable in response to operational power that is applied to the non-bi-stable display. Other display types, such as LCD or electro-chromic, may be provided as well.

Other permanent information, such as permanent information 120, may be included within card 100, which may include user specific information, such as the cardholder's name or username. Permanent information 120 may, for example, include information that is specific to card 100 (e.g., a card issue date and/or a card expiration date). Information 120 may represent, for example, information that includes information that is both specific to the cardholder, as well as information that is specific to card 100.

Card 100 may accept user input data via any one or more data input devices, such as buttons 110-118. Buttons 110-118 may be included to accept data entry through mechanical distortion, contact, or proximity. Buttons 110-118 may be responsive to, for example, induced changes and/or deviations in light intensity, pressure magnitude, or electric and/or magnetic field strength. Such information exchange may then be determined and processed by a processor of card 100 as data input.

Two or more detectors 124 may be implemented to detect, for example, the proximity, or actual contact, of an object, such as a read-head housing of a magnetic stripe reader. Proximity detectors 124 may be utilized, for example, to detect a magnetic stripe reader during a transaction (e.g., a card-based financial transaction) when card 100 is swiped through a read-head housing of the magnetic stripe reader. During such a transaction, dynamic magnetic stripe communications device 102 may be activated in response to such a detection to provide one or more tracks of magnetic stripe data to the detected magnetic stripe reader.

Card 100 may be implemented using architecture 150, which may include one or more processors 154. One or more processors 154 may be configured to utilize external memory 152, internal memory of processor 154, or a combination of external memory 152 and internal memory for storing information, such as executable machine language, related dynamic machine data, non-time smearing gain algorithms and user input data values.

One or more of the components shown in architecture 150 may be configured to transmit information to processor 154 and/or may be configured to receive information as transmitted by processor 154. For example, one or more displays 156 may be coupled to receive data from processor 154. The data received from processor 154 may include, for example, at least a portion of dynamic numbers and/or dynamic codes. The data to be displayed on the display may be displayed on one or more displays 156.

One or more displays 156 may be, for example, touch sensitive and/or proximity sensitive. For example, objects such as fingers, pointing devices, etc., may be brought into contact with displays 156, or in proximity to displays 156. Detection of object proximity or object contact with displays 156 may be effective to perform any type of function (e.g., transmit data to processor 154). Displays 156 may have multiple locations that are able to be determined as being touched, or determined as being in proximity to an object.

Input and/or output devices may be implemented on architecture 150. For example, integrated circuit (IC) chip 160 (e.g., an EMV chip) may be included on architecture 150, that can communicate information with a chip reader (e.g., an EMV chip reader). Radio frequency identification (RFID) module 162 may be included within architecture 150 to enable the exchange of information with an RFID reader.

Other input and/or output devices 168 may be included on architecture 150, for example, to provide any number of input and/or output capabilities. For example, other input and/or output devices 168 may include an audio device capable of receiving and/or transmitting audible information.

Other input and/or output devices 168 may include a device that exchanges analog and/or digital data using a visible data carrier. Other input and/or output devices 168 may include a device, for example, that is sensitive to a non-visible data carrier, such as an infrared data carrier or electromagnetic data carrier.

Persons skilled in the art will appreciate that a card (e.g., card 100 of FIG. 1) may, for example, be a self-contained device that derives its own operational power from one or more batteries 158. Furthermore, one or more batteries 158 may be included, for example, to provide operational power for a period of time (e.g., approximately 2-4 years). One or more batteries 158 may be included, for example, as rechargeable batteries.

Electromagnetic field generators 170-174 may be included on architecture 150 to communicate information to, for example, a read-head of a magnetic stripe reader via, for example, electromagnetic signals. For example, electromagnetic field generators 170-174 may be included to communicate one or more tracks of electromagnetic data to read-heads of a magnetic stripe reader. Electromagnetic field generators 170-174 may include, for example, a series of electromagnetic elements, where each electromagnetic element may be implemented as a coil wrapped around one or more materials (e.g., a magnetic material and/or a non-magnetic material). Additional materials may be placed outside the coil (e.g., a magnetic material and/or a non-magnetic material).

Electrical excitation by processor 154 of one or more coils of one or more electromagnetic elements via, for example, driving circuitry 164 may be effective to generate electromagnetic fields from one or more electromagnetic elements. One or more electromagnetic field generators 170-174 may be utilized to communicate electromagnetic information to, for example, one or more read-heads of a magnetic stripe reader.

Timing aspects of information exchange between the various I/O devices implemented on architecture 150 may be determined by processor 154. One or more proximity detectors 166 may be utilized, for example, to sense the proximity, mechanical distortion, or actual contact, of an external device, which in turn, may trigger the initiation of a communication sequence by processor 154. The sensed presence, mechanical distortion, or touch of the external device may be effective to, for example, determine the type of device or object detected.

For example, the detection may include the detection of, for example, a read-head housing of a magnetic stripe reader. The detection may include a detection of a read-head housing as it moves at a high rate of speed and/or a changing rate of speed in relation to a card (e.g., card 100 of FIG. 1). In response, processor 154 may activate one or more electromagnetic field generators 170-174 to initiate a communications sequence with, for example, one or more read-heads of the magnetic stripe reader.

Persons skilled in the art will appreciate that processor 154 may provide user-specific and/or card-specific information through utilization of any one or more of buttons 110-118, RFID 162, IC chip 160, electromagnetic field generators 170-174, and other input and/or output devices 168.

Turning to FIG. 2, a card is shown having an orientation of detectors 226, whereby one or more detectors 202-216 may be, for example, arranged along a length of card 200. Detectors 202-216 may be provided, for example, as conductive pads using, for example, an additive technique, whereby patterns of a conductive element (e.g., copper) may be applied to a PCB substrate according to a patterning mask definition layer. Detectors 202-216 may be provided, for example, as conductive pads using, for example, a subtractive technique whereby patterns of a conductive element (e.g., copper) may be removed from a pre-plated PCB substrate according to an etching mask definition layer. Other non-PCB fabrication techniques may be used to implement conductive pads 202-216 as may be required by a particular application.

Detection circuitry 220 of processor 218, conductive pads 202-216, processor 218, and non-time smearing gain algorithm 230 may be combined to provide a detection system. Persons skilled in the art will appreciate that any number of conductive pads may be utilized by a processor as capacitive sensing pads. Particularly, a processor may include the functionality to control a detection system to determine when an object is in the proximity of one or more conductive pads via a capacitive sensing technique.

FIG. 3 shows detection circuitry 300. A conductive pad may be utilized, for example, as a conductor of a capacitive device within a resistor/capacitor (RC) circuit to determine the capacitance of a conductive pad and determine whether the capacitance is below, equal to, or above one or more predetermined thresholds.

A conductive pad may, for example, form a portion of a capacitive element, such that plate 316 of capacitive element 314 may be implemented by a conductive pad and the second plate of capacitive element 314 may be implemented by element 310. Element 310 may represent, for example, the device or object whose proximity or contact is sought to be detected.

The capacitance magnitude of capacitive element 314 may exhibit, for example, an inversely proportional relationship to the distance separation between plate 316 and device 310. For example, the capacitance magnitude of capacitive element 314 may be relatively low when the corresponding distance between plate 316 and device 310 may be relatively large. The capacitance magnitude of capacitive element 314 may be relatively large, for example, when the corresponding distance between plate 316 and device 310 is relatively small.

Detection may be accomplished, for example, via circuit 300 of FIG. 3. Through a sequence of charging and/or discharging events, a capacitance magnitude change for capacitive element 314 may be monitored over a given period of time. In so doing, for example, the spatial relationship (e.g., the separation distance) between plate 316 and device 310 may be approximated.

Charge sequence 350 may, for example, be optionally invoked, such that charge circuit 304 may be activated at time T1, while discharge circuit 306 may remain deactivated. Accordingly, for example, current may flow through resistive component 308. In doing so, for example, an electrostatic field may be generated that may be associated with capacitive component 314.

During the charge sequence, for example, the voltage at node 312 may be monitored to determine the amount of time required (e.g., T_(CHARGE)=Δ1−T1) for the voltage at node 312, V₃₁₂, to obtain a magnitude that is substantially equal to, below, or above a first threshold voltage (e.g., equal to V1).

Discharge sequence 360 may, for example, be optionally invoked, such that discharge circuit 306 may be activated at time T2, while charge circuit 304 may remain deactivated. During the discharge sequence, for example, the electric field associated with capacitive element 314 may be allowed to discharge through resistive component 308 to a reference potential (e.g., ground potential). The voltage at node 312 may be monitored to determine the amount of time required (e.g., T_(DISCHARGE)=Δ2−T2) for the voltage at node 312, V₃₁₂, to obtain a magnitude that is substantially equal to, below, or above a second threshold voltage (e.g., equal to V2).

Once the charge time, T_(CHARGE), and/or discharge time, T_(DISCHARGE), are determined, the charge and/or discharge times may be utilized to calculate a capacitance magnitude that may be exhibited by capacitive element 314. For example, given that the magnitude of voltage, V1, may be equal to approximately 63% of the magnitude of voltage, V_(s), then a first relationship may be defined by equation (1) as:

T _(CHARGE) =R ₃₀₈ *C1,   (1)

where R₃₀₈ is the resistance magnitude of resistive element 308 and C1 is proportional to a capacitance magnitude of a capacitive element (e.g., capacitive element 314).

Similarly, for example, given that the magnitude of voltage, V2, is equal to approximately 37% of the magnitude of voltage, V_(s), then a second relationship may be determined by equation (2) as:

T _(DISCHARGE) =R ₃₀₈ *C2,   (2)

where C2 is proportional to a capacitance magnitude of capacitive element 314. The capacitance magnitudes, C₁ or C₂, may then be calculated from equations (1) or (2), respectively, and taken by themselves to determine a capacitance magnitude that may be exhibited by capacitive element 314. Alternatively, for example, capacitance magnitudes, C₁ and C₂, may be calculated from equations (1) and (2), respectively, and averaged to determine a capacitance magnitude that may be exhibited by capacitive element 314.

Persons skilled in the art will appreciate that circuits 304 and/or 306 may be activated and deactivated by controller 320. Accordingly, for example, controller 320 may control when the charge and/or discharge events occur. Persons skilled in the art will further appreciate that controller 320 may adjust a frequency at which circuits 304 and 306 may be activated and/or deactivated, thereby adjusting a sampling rate at which the capacitance magnitudes, C₁ and/or C₂, may be measured. Accordingly, for example, controller 320 may implement a detection algorithm (e.g., non-time smearing gain algorithm 318) to determine a position, velocity and/or an acceleration of an object based on the processing of relative capacitance magnitude variations of a series of pads over time in accordance with such an algorithm.

Turning back to FIG. 2, for example, a series of charge and/or discharge cycles for pads 202-216 may be executed by processor 218 to determine, for example, a relative capacitance magnitude that may be exhibited by each of pads 202-216. A series of charge and/or discharge cycles for each of pads 202-216 may be executed by processor 218, for example, in order to obtain a capacitance characteristic for each of pads 202-216 over time, thereby determining whether an object (e.g., a read-head housing of a magnetic stripe reader) is within a proximity to card 200, whether that object is moving with respect to card 200 and if so, what direction that object is moving and/or whether that object is accelerating with respect to card 200.

Processor 218 may, for example, measure the charge time (e.g., T_(CHARGE) of equation (1)) and/or the discharge time (e.g., T_(DISCHARGE) of equation (2)) by counting a number of periods of an oscillation signal (e.g., an oscillation signal generated within processor 218) that are required to achieve the respective voltage threshold values (e.g., V1 and/or V2 of FIG. 3) for each of pads 202-216 over a period of time. Processor 218 may, for example, implement a filtering/averaging algorithm in accordance with equation (3) to compute a number of periods, Count[n], of an oscillation signal that are required to achieve the respective voltage threshold value for the n^(th) pad of an array of N pads over a period of time.

Count[n(t)]=Count[n(t−1)]+New Count−(Count[n(t−1)]+1)/2   (3)

where Count[n(t−1)] is the number of periods of an oscillation signal that were required for the n^(th) pad of a pad array having N pads to achieve its respective voltage threshold level during the previous charge and/or discharge cycle and where New Count is the number of periods of an oscillation signal that were required for the n^(th) pad of a pad array having N pads to achieve its respective voltage threshold level during a subsequent charge and/or discharge cycle.

The algorithm of equation (3) may, for example, filter out capacitance detection variations for the n^(th) pad of an N pad array due to noise (e.g., detection sensitivity variation, quantization noise and power supply noise). However, the algorithm of equation (3) may also tend to smear detection results across adjacent time periods by using the previous detection results in a calculation of the current detection results, thereby providing an artificial “lengthening” of each detection pad.

Accordingly, for example, as swipe speeds increase, an alternate algorithm (e.g., non-time smearing algorithm 230) may be implemented to eliminate the time-smearing effects that may prohibit an accurate detection of the position, velocity and/or acceleration of an object (e.g., a read-head housing of a magnetic stripe reader) that may be in proximity to card 200. For example, a non-time smearing algorithm in accordance with equation (4) may be used to obtain a more accurate count for specific pads of interest in real time.

Count[n(t)]=New Count*Gain Value,   (4)

where New Count is the number of periods of an oscillation signal that were required for the n^(th) pad of a pad array having N pads to achieve its respective voltage threshold level during the current charge and/or discharge cycle and Gain Value is an integer multiplier (e.g., 2, 4, 8 or 16).

By comparing the time-based capacitance characteristic of each pad 202-216, as may be approximated by equations (3) or (4), to a threshold capacitance value, a determination may be made, for example, as to when pads 202-216 are in a proximity, or touch, relationship with a device whose presence is to be detected. For example, a sequential change (e.g., increase) in the relative capacitance magnitudes of pads 202-208, respectively, and/or pads 216-210, respectively, may be detected and a determination may be made that a device is moving substantially in direction 222 relative to card 200. A sequential change (e.g., increase) in the relative capacitance magnitudes of detectors 210-216, respectively, and/or 208-202, respectively, may be detected, for example, and a determination may be made that a device is moving substantially in direction 224 relative to card 200.

Persons skilled in the art will appreciate that by electrically shorting pairs of detectors together (e.g., pair 202/210, pair 204/212, pair 206/214, etc.) directional vectors 222 and 224 become insubstantial. For example, regardless of whether a device is moving substantially in direction 222 or substantially in direction 224 relative to card 200, a determination may nevertheless be made that a device is close to, or touching, card 200.

Detection circuitry 220 of processor 218 may be used in conjunction with, for example, one or more pads 202-216 to determine that a device (e.g., a read-head housing of a magnetic stripe reader) is in close proximity, or touching, one or more of pads 202-216. Processor 218 may, for example, utilize non-time smearing gain algorithm 230 to detect a device when that device is moving at a relatively high rate of speed with respect to card 200. For example, non-time smearing gain algorithm 230 may detect a capacitance change in a conductive pad during a time period, without consideration of a capacitance change in that conductive pad during previous time periods, to determine that a device is moving in relation to pads 202-216. Once a device is detected, processor 218 may, for example, communicate with the detected device via dynamic magnetic stripe communications device 228.

FIG. 4 shows a card that is in proximity to a device (e.g., a read-head of a magnetic stripe reader). Card 415 may be in proximity to a device such that a distance between conductive pad 406 and read-head 402 is less than a distance between conductive pad 408 and read-head 402. Accordingly, for example, a relative capacitance magnitude that may be associated with conductive pad 406 may be, for example, greater than a relative capacitance magnitude that may be associated with conductive pad 408. In so doing, for example, a processor that may be monitoring the relative capacitance magnitudes of conductive pads 406 and 408 may determine that a device is closer to conductive pad 406 than to conductive pad 408 by applying a non-time smearing gain algorithm to more accurately detect a capacitance change in pads 406 and 408 without applying any capacitance change results that may have been detected for pads 406 and 408 in previous time periods.

Card 425 may be in proximity to a device (e.g., read-head 412) that may have moved from position 420 such that a distance between conductive pad 418 and device 412 may be slightly greater than a distance between conductive pad 416 and device 412. Accordingly, for example, a capacitance magnitude that may be associated with conductive pad 416 may be, for example, slightly greater than a capacitance magnitude that may be associated with conductive pad 418. In so doing, for example, a processor that may be monitoring the capacitance magnitudes of conductive pads 416 and 418 may determine that a device may be travelling in direction 414. Further, a processor may determine that a device is slightly closer to conductive pad 416 than to conductive pad 418 by applying a non-time smearing gain algorithm to more accurately detect a capacitance change in pads 416 and 418 without applying any capacitance change results that may have been detected for pads 416 and 418 in previous time periods.

Card 435 may be in proximity to a device (e.g., read-head 422) that may have moved from position 432 to 434. Accordingly, for example, a capacitance magnitude that may be associated with conductive pad 428 may be slightly greater than a capacitance magnitude that may be associated with conductive pad 426. In so doing, for example, a processor that may be monitoring the capacitance magnitudes of conductive pads 426 and 428 may determine that a device may be travelling in direction 424. Further, a processor may determine that a device is slightly closer to conductive pad 428 than to conductive pad 426 by applying a non-time smearing gain algorithm to more accurately detect a capacitance change in pads 426 and 428 without applying any capacitance change results that may have been detected for pads 426 and 428 in previous time periods.

Device 422 may move from position 434 to position 436. Accordingly, for example, a capacitance magnitude that may be associated with conductive pad 430, for example, may be slightly greater than a capacitance magnitude that may be associated with conductive pad 428. In so doing, for example, a processor that may be monitoring the capacitance magnitudes of conductive pads 430 and 428 may determine that a device may be travelling in direction 424.

Further, a processor may determine, for example, that a device is first located closest to conductive pad 426, the device is then located closest to conductive pad 428, and the device is then located closest to conductive pad 430 in succession by detecting, for example, that a capacitance magnitude of conductive pad 426 changes (e.g., increases), followed by a capacitance change (e.g., increase) of conductive pad 428 by applying a non-time smearing gain algorithm to more accurately detect a capacitance change in pads 426 and 428 without applying any capacitance change results that may have been detected for pads 426 and 428 in previous time periods, and then followed by a capacitance change (e.g., increase) of conductive pad 430 by applying a non-time smearing gain algorithm to more accurately detect a capacitance change in pads 428 and 430 without applying any capacitance change results that may have been detected for pads 428 and 430 in previous time periods. In response to a sequential capacitance change in pads 426, 428, and 430, respectively, a processor may activate one or more electromagnetic field generators to initiate a communications sequence with, for example, read-head 422.

FIG. 5 shows a card that is in proximity to a device (e.g., read-head 510 of a magnetic stripe reader). Card 502 may provide a first set of conductive pads (e.g., pads 512-520) that may be used by a processor of card 502, for example, to initially detect a device (e.g., read-head 510) that may be in proximity to card 502 or that may be touching card 502. Further, a processor of card 502 may detect movement of read-head 510 in direction 522 at locations 504, 506, and 508 by applying a non-time smearing gain algorithm to more accurately detect a capacitance change in pads 514 and 516, for example, without applying any capacitance change results that may have been detected in previous time periods for pads 512 and 514, respectively. In response, a processor of card 502 may be placed on standby and thereby readied to activate one or more electromagnetic field generators to initiate a communications sequence with, for example, read-head 510.

Card 502 may provide a second set of conductive pads (e.g., pads 532-540) that may be used, for example, to provide detection verification of a device (e.g., read-head 530). Accordingly, for example, a presence of a device may be twice detected, for example, so as to confirm that a device was accurately detected and a processor of card 502 may then commence communications with that device.

Post-detection verification may be useful, for example, to reduce false alarm detections of a device. For example, a processor of card 502 may verify through post-detection verification that a presence of a device (e.g., a read head of a magnetic stripe reader as opposed to any other type of device) was reliably detected and that a communication sequence with the device may then commence. In so doing, for example, a processor of card 502 may reduce power consumption by requiring a second detection in succession to a first detection before establishing communications with the device.

A flow diagram of a detection activity is shown in FIG. 6. Step 611 of sequence 610 may initiate a detection operation, for example, where a property change (e.g., an increased capacitance) associated with a conductive pad is detected during a first time period. A property change (e.g., a capacitance increase) may then be detected in the conductive pad during a second time period (e.g., as in step 612). A relative property change detected in the first time period is not allowed to affect a relative property change detected in the second time period (e.g. as in step 613) by applying a non-time smearing gain algorithm. In so doing, a detection activity may be sensitive to property changes detected in a conductive pad during a time period that is independent of property changes detected in the conductive pad during one or more previous time periods.

In step 621 of sequence 620, a property change (e.g., an increased capacitance) associated with a pad of a first set of pads may be detected during a first time period. A property change (e.g., a capacitance increase) may then be detected in the pad of the first set of pads during a second time period (e.g., as in step 622), where a relative capacitance change detected in the first time period is not allowed to affect a relative capacitance change detected in the second time period by applying a non-time smearing gain algorithm. In step 623, a processor may prepare a dynamic magnetic stripe communications device for communication, but may refrain from activating the dynamic magnetic stripe communications device until a verification detection occurs.

In step 624, a property change (e.g., an increased capacitance) associated with a pad of a second set of pads may be detected during a third time period. A property change (e.g., a capacitance increase) may then be detected in the pad of the second set of pads during a fourth time period (e.g., as in step 625), where a relative capacitance change detected in the third time period is not allowed to affect a relative capacitance change detected in the fourth time period by applying a non-time smearing gain algorithm. In step 626, after two detections in succession, a processor may activate a communication sequence (e.g., a dynamic magnetic stripe communications device may communicate a first, a second and/or a third track of magnetic stripe information to a detected read head of a magnetic stripe reader).

Persons skilled in the art will also appreciate that the present invention is not limited to only the embodiments described. Instead, the present invention more generally involves dynamic information and the exchange thereof. Persons skilled in the art will also appreciate that the apparatus of the present invention may be implemented in other ways than those described herein. All such modifications are within the scope of the present invention, which is limited only by the claims that follow. 

1. (canceled)
 2. A device, comprising: a plurality of pads; and a controller operable to receive information associated with relative capacitance magnitude variations of the plurality of pads over time, and process the information using a non-time smearing gain algorithm to determine a position of an external object.
 3. A device, comprising: a plurality of pads; and a controller operable to receive information associated with relative capacitance magnitude variations of the plurality of pads over time, and process the information according to a non-time smearing gain algorithm to determine a velocity of an external object.
 4. A device, comprising: a plurality of pads; and a controller operable to receive information associated with relative capacitance magnitude variations of the plurality of pads over time, and process the information according to a non-time smearing gain algorithm to determine an acceleration of an external object. 